The author of 《An effective surface modification strategy with high reproducibility for simultaneously improving efficiency and stability of inverted MA-free perovskite solar cells》 were Zhu, Hongmei; Wu, Shaohang; Yao, Jiaxu; Chen, Rui; Pan, Ming; Chen, Weitao; Zhou, Jing; Zhang, Wenjun; Wang, Tao; Chen, Wei. And the article was published in Journal of Materials Chemistry A: Materials for Energy and Sustainability in 2019. Application of 1122-54-9 The author mentioned the following in the article:
Perovskite solar cells (PSCs) have become the front-running photovoltaic technol. and have triggered enormous research interest worldwide owing to their ultra-high solar-to-elec. power conversion efficiency and low fabrication costs, but their poor intrinsic stability issues still constitute the main obstacles that hinder their rapid commercialization. Herein, we demonstrate that, by carefully designing the modifier’s mol. structure, a facile, highly reproducible and scalable surface modification strategy can effectively enhance both the stability and efficiency of inverted PSCs. The most efficient modifier (2-acetylpyridine) can not only passivate the surface traps of the perovskite film but also enhance its stability against moisture by forming a hydrophobic capping layer on top. Accordingly, the efficiency of the inverted PSC has been improved from 16.75% to 20.05% for the best-performing one, which is, to our knowledge, among the highest values for inverted MA-free PSCs. More encouragingly, the stability of the modified devices can also be largely enhanced: the devices retained 95%, 90%, and 91% of their initial efficiencies after storage in the dark in ambient air for 2000 h, 85°C thermal aging for 500 h in the dark, and light soaking at 45°C for 500 h, resp. In the experiment, the researchers used 4-Acetylpyridine(cas: 1122-54-9Application of 1122-54-9)
4-Acetylpyridine(cas: 1122-54-9) belongs to pyridine. Pyridine derivatives lend themselves to many roles in the spirited field of supramolecular chemistry – whether as the ligand backbone of metal-organic polymers or presiding over the key electronic stations of nanodevices. In biochemistry, pyridine-containing cofactors are necessary nutrients on which our lives depend. Application of 1122-54-9